Открытый доступ  Платный доступ или доступ для подписчиков

Рассмотрены основные направления развития аддитивных технологий в Санкт-Петербургском политехническом университете Петра Великого. Приведены примеры разработок: исследование и получение сферических порошков сложнолегированных сплавов для аддитивного производства из металлоотходов; изготовление и исследование функционально-градиентных материалов с переменной структурой, химическим составом и пористостью; синтез интерметаллидных титановых сплавов методом селективного лазерного плавления и др.

аддитивные технологии; функционально-градиентные материалы; металлический порошок; микроструктура; additive technologies; functionally graded materials; metallic powder; microstructure

Santos E. C. et al. Rapid manufacturing of metal components by laser forming // Int. J. Mach. Tools Manuf. 2006. V. 46, No. 12 - 13. P. 1459 - 1468.

Maksarov V., Krasnyy V. The formation of surface roughness of piston rings for the purpose of improving the adhesion of wear-resistant coatings // Key Engineering Materials. 2017. V. 736 KEM. P. 73 - 78.

Olt J., Liivapuu O., Maksarov V., Liyvapuu A., Tдrgla T. Mathematical modelling of cutting process system // Springer Proceedings in Mathematics and Statistics. 2016. V. 178. P. 173 - 186.

Frazier W. E. Metal additive manufacturing: A review // Journal of Materials Engineering and Performance. 2014. V. 23, No. P. 1917 - 1928.

Wohlers T. Wohlers Report 2014: Additive Manufacturing and 3D Printing State of the Industry. Annual Worldwide Progress Report. Wohlers Associates Inc. 2014. 275 p.

Uriondo A., Esperon-Miguez M., Perinpanayagam S. The present and future of additive manufacturing in the aerospace sector: A review of important aspects: Proceedings of the Institution of Mechanical Engineers, Part G // Journal of Aerospace Engineering. 2015. V. 229, No. 11. P. 2132 - 2147.

Sing S. L. et al. Laser and electron-beam powder-bed additive manufacturing of metallic implants: A review on processes, materials and designs // Journal of Orthopaedic Research. 2016. V. 34, No. 3. P. 369 - 385.

Mahmoud D., Elbestawi M. Lattice structures and functionally graded materials applications in additive manufacturing of orthopedic implants: a review // Journal of Manufacturing and Materials Processing. 2017. V. 1, No. 2. P. 1 - 19.

Popovich V. A., Borisov E. V., Sufiyarov V. S. et al. Tailoring the properties in functionally graded alloy Inconel 718 using additive technologies // Met. Sci. Heat Treat. 2019. V. 60, No. 11 - 12. P. 701 - 709.

Masaylo D. V., Popovich A. A., Sufiyarov V. S. et al. A study of structural features of a gradient material from a heat-resistant nickel alloy produced by laser cladding // Met. Sci. Heat Treat. 2019. V. 60, No. 11 - 12. P. 739 - 744.

Singh S., Ramakrishna S., Singh R. Material issues in additive manufacturing: A review // Journal of Manufacturing Processes. 2017. V. 25. P. 185 - 200.

Samal S. Thermal plasma technology: The prospective future in material processing // Journal of Cleaner Production. 2017. V. 142. P. 3131 - 3150.

Razumov N. G., Popovich A. A., Wang Q. S. Thermal plasma spheroidization of high-nitrogen stainless steel powder alloys synthesized by mechanical alloying // Metals and Materials International. 2018. V. 24, No. 2. P. 363 - 370.

Polozov I. et al. Selective laser melting of Ti2AlNb-based intermetallic alloy using elemental powders: Effect of process parameters and post-treatment on microstructure, composition, and properties // Intermetallics. 2019. V. 112. Art. 106554.

Polozov I. et. al. Synthesis of titanium orthorhombic alloy spherical powders by mechanical alloying and plasma spheroidization processes // Materials Letters. 2019, 126615.

Borkar T. et al. A combinatorial assessment of AlxCrCuFeNi2 (0 < x № 1.5) complex concentrated alloys: Microstructure, microhardness, and magnetic properties // Acta Materialia. 2016. V. 116. P. 63 - 76.

Panchenko O. V., Zhabrev L. A., Kurushkin D. V. et al. Macrostructure and mechanical properties of Al - Si, Al - Mg - Si, and Al - Mg - Mn aluminum alloys produced by electric arc additive growth // Met. Sci. Heat Treat. 2019. V. 60, No. 11 - 12. P. 749 - 754.